Effect of microfracture and autologous-conditioned plasma application in the focal full-thickness chondral defect of the knee: an experimental study on rabbits

In the present study, we found that ACP injection intraarticularly or both intraarticularly and subperiosteally into a defect covered by periosteum may enhance cartilage repair in the treatment with microfracture of focal full-thickness chondral defect in the knee.

Microfracture is the most well-studied marrow-stimulation procedure and involves the arthroscopic penetration of the subchondral plate with an awl. The creation of channels in the subchondral plate allows for the influx of blood, blood-derived cells, and bone marrow-derived mesenchymal stem and progenitor cells (MSCs) into the defect, forming a blood clot populated with platelets, growth factors, and bone marrow-derived pluripotent stem cells to allow for the remodeling of the fibrin clot in the defect into fibrocartilage repair tissue [4‐9]. Although microfractures provide good short-term outcomes for many patients, mid- to long-term studies have demonstrated gradual decreases in functional outcomes after 24 to 36 months, potentially due to tissue degradation overtime [4, 5, 11, 13]. This could be explained because of the less durable fibrocartilage produced after microfracture and the poor integration of this tissue with the native cartilage. This fact is also consistent with the results of the current study, since in the mfx treated group, the newly formed tissue that filled the defect was fibrocartilage. Therefore, methods for the advancement of the microfracture technique are demanded that may enhance the content of key matrix components and improve the cartilaginous repair tissue such as scaffold enhancement, hyaluronic acid viscosupplementation, cytokine modulation techniques, and PRP injections [7‐13].

The simple rationale supporting the use of PRP to treat cartilage injuries lies in the concept that PRP provides a milieu of bioactive growth factors such as transforming growth factor beta (TGF-β), platelet-derived growth factor (PDGF), insulin-like growth factor-1 (IGF-1), and vascular endothelial growth factor (VEGF) that have synergistic effects on cartilage matrix synthesis and mitigate the effects of catabolic cytokines such as interleukin-1 (IL-1) and tumor necrosis factor-α (TNF-α). PRP was also found to increase the cell viability of chondrocytes, the migration and chondrogenic differentiation of MSCs, increasing chondrocyte and mesenchymal stem cell proliferation, proteoglycan deposition, and type II collagen deposition. Different results have been reported on the application of PRP in chondral lesions. Not all studies concluded that PRP has a positive effect on cartilage repair [31]. In the study by Vaisman et al., the use of intraarticular BMS or PRP as coadjuvants to the microfracture technique for the treatment of acute chondral lesions was not associated with a significant improvement of hyaline cartilage regeneration [32]. This conclusion was only valid for the dosage used in that particular study (one intraarticular dose of 0.4 mg of betamethasone). Perhaps the PRP concentration was not sufficient to promote chondral healing. On the other hand, results from most animal studies have identified the potential utility of autologous platelets, both in isolation and as an adjunct to surgical procedures, to restore normal hyaline cartilage in articular injuries. The results of these studies have shown that the platelet supernatant stimulate chondrocyte proliferation and may form a scaffold for chondrocytes. Chondrocytes stimulated with PRP in vitro has been shown to increase synthesis of proteoglycans and collagen with the repair tissue generated after PRP treatment, demonstrating similar histological and biomechanical characteristics to normal hyaline cartilage [15‐28, 32]. Milano et al. performed experimental studies on the effect of autologous PRP with microfracture on chondral defects in a sheep model and reported that treatment with PRP revealed an improvement of cartilage stiffness and showed higher ICRS scores [22, 23]. Similar positive results in chondral defect reconstruction with autologous platelets were found in the present study. An improvement in macroscopic observation was observed in groups that were treated with ACP, and histological analysis further supported these findings. In fact, within the criteria evaluated according to the histological ICRS score, all criteria showed a significant improvement with the use of ACP associated with microfracture compared to the microfracture treatment alone. ACP injection might effectively modify the joint microenvironment in order to facilitate cartilage regeneration. In the present study, in addition to the intraarticular ACP application, we also investigated the effectiveness of both ACP application into the defect covered by the periosteum and intraarticular ACP application. In Groups 2 and 3, hyaline-like cartilage was observed in knee defects; however, hyaline-like cartilage was more abundant in Group 3. In the same groups, all animals presented better chondral cellularity and regeneration and lower fibrosis. Among all groups, we observed the poorest healing in Group 1 and the best healing in Group 3. Furthermore, we discovered that augmenting the defect using periosteum to cover the defect (as a scaffold) and subperiosteal and intraarticular ACP injection was superior over microfracture application with respect to cartilage repair.

We believe that periosteum both contributes to joint regeneration, and as a scaffold, it can maintain thrombocyte concentration and growth factors for a longer time within ACP, thus, providing an advantage in obtaining a more hyaline-like cartilage and better results in periosteum-administered groups. Moreover, we believe that reporting different results after PRP application results from the differences in the methods of obtaining PRP, its concentration, method of activation, dose, and method for applying PRP [1]. In the current study, the preparation of PRP was performed according to the protocol described by Borzini et al. [15]. In their study, autologous PRP was used without performing a platelet count, which constitutes evidence that PRP can be prepared using this protocol.

This is a preliminary study, and hence, has certain limitations. The current study included a histological evaluation of the repair tissue for only up to 12 weeks after surgery and on a limited number of animals as well as periosteum that have many disadvantages that might not have been obvious in this short-term follow-up. Increasing the number of animals, and creating groups to include longer and different time periods, would increase the strength of the study. We only evaluated morphological parameters and could not demonstrate the effectiveness of ACP at the molecular levels. The lack of mechanical evaluation of the repair tissue is a shortcoming of this study. We did not analyze the plasma thrombocyte levels in the present study. According to the manufacturer’s reference, this procedure results in a 3-fold increase in thrombocyte count and a 2- to 6-fold increase in growth factor levels (EGF, VEGF, TGF-β, PDGF) [14, 28].

In conclusion, in the present study, we were able to demonstrate a beneficial effect of intraarticular administration of platelet-rich plasma as a coadjuvant of microfractures in order to regenerate hyaline-like cartilage in full-thickness chondral lesions in a rabbit model. Further researches with well-designed randomized controlled trials (RCTs) are required to validate the findings of this study in clinical settings.